JP2005529396A - Method for optimizing presentation on a display screen of freely positionable and scalable objects - Google Patents

Abstract

The present invention relates to a method for optimizing the on-screen representation of user interface objects that can be freely positioned and scaled by control elements. This is possibly a display screen that can be used while suppressing less important details of the object content, changing the object content and / or the mode of display of the objects, and avoiding overlapping of the objects. The object between the smallest readable dimension and the largest selected dimension according to the object content, selected desired settings, and available display resources on the display screen, so that optimal filling of the surface is achieved Is performed by the control element according to a predetermined calculation rule so that can be automatically changed.

Description

  The present invention relates to a method for optimizing the presentation on a display screen of a user interface object that can be freely positioned and scaled by a control means.

  Today's computers are known to be operated via so-called user interfaces that present relevant operating system functions or applications in the form of graphical objects (windows).

  Such user interfaces are particularly popular in the field of personal use due to their user-friendly nature. In this regard, reference may be made, for example, to the graphic user interface “(registered trademark) Microsoft Windows”. However, both in the technical field, for example, generally in the field of patient monitoring, graphic user interfaces are often used because they allow for the simultaneous presentation of multiple objects on a display screen. For example, in medical applications, these objects are related to blood pressure, heart rate, etc., and their deformations are represented graphically.

  The user usually has the possibility to move the object on the surface of the display screen to scale the object and set the type of presentation, i.e. to place multiple objects on the display screen individually. Yes. However, manipulation of the object content, ie the information to be displayed, is usually not possible at all or only to a limited extent. For example, if only the contents of a directory are to be displayed, the user automatically receives additional information in the form of the file size of the individual files. Since the display resources on the display screen are limited, it is not possible to automatically suppress such additional information. As a result, the object content and thus the information to be displayed remains the same.

  The object content also remains the same in case of object scaling. For example, when an object is reduced, an additional scroll list is often provided on the side to allow continuous observation of the object contents. For example, it is not possible to automatically adapt the object content so that less important information is automatically suppressed because it is a smaller representation.

  The same is true when zooming on object content. In that case, only simple enlargement / reduction of the entire object content by a predetermined coefficient is performed. For example, it is not possible to apply the object content such that only the details of the object content are enlarged / reduced.

  Automatic adaptation of the user interface to changing operating environments is also usually not possible. For example, when a computer is used as a measurement computer and the user configures the user interface so that several measurement columns can be displayed simultaneously as objects and one of the measurements does not temporarily give a result Only the measured values that do not give a result are displayed as information. It is not possible to automatically switch the display to other available measurement columns.

  Certainly, some user interfaces in the field of patient monitoring have functions for limited adaptation to changing environments, but such user interfaces allow the user to individually adjust the size and position of objects. Has the disadvantage of not being able to.

  Accordingly, the present invention provides a method for presenting an object on a user interface that can be freely positioned and scaled by a control element, thus allowing for optimal display of object content while avoiding the aforementioned drawbacks. For the purpose.

  According to the invention, this object is achieved as disclosed in claim 1. Further features of the invention are disclosed in the dependent claims.

  The present invention recognizes that calculation rules can be applied to transform an object to be displayed into an intelligent object such as a computer, thus allowing an optimal representation of the object or object content in the user surface. based on.

  In accordance with the present invention, an object is selected between a minimum readable dimension and a maximum selected dimension according to the object content, the desired setting selected, and the available display resources on the display screen. Available by calculation rules, i.e. possibly suppressing less important details of the object content, changing the object content and / or the mode of display of the object, and avoiding overlapping of objects Can be automatically changed to achieve optimal filling of the correct display screen surface. Such automatic adaptation of objects also holds for all kinds of objects or object contents that are to be presented continuously on the user interface so that they are clearly arranged.

  For example, the object or object content may be dynamically variable information such as a temporary recording of measured values, static information such as directory output, as well as commands and various options for further processing / operation (hereinafter Or a menu button).

  This is very advantageous in the case of patient monitoring because for a user, for example a doctor or nurse, all important information such as selected patient information and associated menu buttons are further processed / operated. This is because it is continuously presented in an optimally readable form on the display screen. Thus, time-consuming manual adjustment of the display screen surface is no longer necessary.

  According to the present invention, if the display resources on the display screen are insufficient, the objects are arranged in a fixed hierarchical structure so that the objects can be automatically suppressed starting from the lowest hierarchical level. The As a result of automatic suppression of less important objects, the display resources made available in this way ensure a clearer display of the remaining object content on the display screen in a simple manner.

  Due to the flexibility, the order of hierarchically combined objects can be changed. For example, objects can be added and removed. However, it is also possible to form an intermediate hierarchical structure, for example in order to ensure a higher clarity in the case of a large number of hierarchically connected objects.

  Multiple objects can be combined to form groups with control elements. Combining multiple objects to form a group provides the advantage that adjustments can be easily made to multiple objects simultaneously. The respective adaptability is maintained for individual objects. For example, if a group of objects is reduced so that the readability of all objects in this group is no longer guaranteed, the less important objects in the group are automatically deleted and the remaining combined objects in the group Optimum readability is ensured. Instead of suppressing individual objects in the group, the object representation of the individual objects in the group can be changed, for example the representation of the individual objects can be changed as a so-called switching surface. In that case, such a switching surface is again an optimized representation of an intelligent object-only surface.

  The preferred embodiment of the present invention takes into account the movement of objects relative to each other, as well as the interaction of various objects relative to each other associated with display resources. This is particularly advantageous with respect to the ease of operation and optimal use of display resources. For example, if a special setting is realized for a first object via a menu function and this special setting requires further adjustment via a menu function for the second object, A corresponding second menu for the object is automatically displayed. Further, for example, when a larger on-screen display is desired, the adapted behavior of the objects relative to each other ensures automatic adaptation of the objects to additional display resources. For example, objects such as the menu buttons described above can also show pictograms if they are appropriate display resources, and these pictograms are automatically deleted again when the display resources become inappropriate.

  With respect to the adapted movement of the objects relative to one another, the further feature relating to the fact that the objects can be automatically replaced with one another is particularly advantageous. For example, if the object does not temporarily generate the data, a second object that conveys the data is automatically displayed instead.

  According to the invention, the object can be temporarily displayed in an enlarged form, depending on a predetermined trigger signal generated by a control element defined by object selection / object marking. This feature is particularly advantageous with respect to ease of operation. For example, if the user needs a certain object, such as a menu button, the user can temporarily display the object in an enlarged form on the user interface by simply “touching” with the cursor, and thus Simple selection is possible.

  Preferably, each rectangular surface is provided for the display of objects on the display screen. A rectangular surface provides the advantage that the object can be easily positioned on the display screen, ensuring optimal use of the available display screen surface.

  According to a preferred embodiment of the present invention, medical information, in particular patient monitoring information, is used as object content.

  The invention also relates to an apparatus for simultaneous compressed optical display of object data on a graphic user interface, the apparatus comprising an arithmetic unit for performing the method. Arithmetic units follow pre-determined criteria, possibly suppressing less important details of object content, changing object content and / or modes of display of objects, and avoiding overlapping of objects Having a calculation program that optimizes the display of object data, the filling of available display screen surfaces is optimal.

  Also provided is a control element that can generate a trigger signal for a short time expansion of the selected / marked object.

  Also, an input means that can change the display is provided. The input means cooperates with a medical measuring device that forms static and dynamic information of the object.

  Further advantages and possible applications of the invention will become apparent from the following description with reference to the illustrated embodiments. Hereinafter, the present invention will be schematically described based on examples of medical applications as shown in the drawings. However, the present invention is not limited to any method. In the specification, claims, abstract, and drawings of this application, the terms and associated reference signs as set forth in the attached list of reference signs shall be used.

  FIG. 1 shows a user interface 10 of the type used for patient monitoring. The user interface 10 includes a plurality of rectangular objects 12. For the sake of clarity, in FIG. 1, only three objects are provided with reference numeral 12.

  The arrangement of the rectangular objects 12 is selected so that the individual objects do not overlap. The surface area of each rectangular object 12 corresponds to a space that can be used to represent the object content on the surface of the display screen (hereinafter referred to as display resource).

  The user interface 10 or the object 12 of the user interface 10 is set individually by a dedicated control element (not shown) such as a keyboard, mouse, pen, etc., in a manner known per se at any time. sell. For example, the placement of individual objects relative to each other can be adjusted at will, and the dimensions of the objects here can also be scaled individually.

FIG. 2 shows the user interface 10 of FIG. 1 with associated object content. As described above, the object to be displayed can be selected at will. Specifically in this example, a plurality of dynamically changing patient data such as an ECG (electrocardiogram) curve (derivative I) 14, a further ECG curve (derivative II) 16, an oxygen saturation curve 18, and a CO ₂ breathing curve 20 are Shown in the form of a curve. On the right side of the curves 14, 16, 18, and 20, the values of the corresponding curves are shown in numerical display form. For example, adjacent to the ECG curve 14, the instantaneous heart rate 22 is shown with an associated alarm limit 24. The same is true for curves 16-20.

  Additional patient information displayed on the user interface 10 relates to blood pressure 26, first body temperature 28, and second body temperature (different measurement locations) 30, and associated alarm limits 32, 34, and 36. To do.

  For example, a plurality of objects 12 (referred to herein as menu buttons 38) are provided in the lower area in order to make adjustments to the user interface 10 such as changing the alarm volume. Adjustment by the menu button can be performed by various input means such as a keyboard, a mouse, a pen element, or by touch screen input.

  All objects 12 are optimally filled with available display screen surfaces, possibly suppressing less important details of the object content and changing the object content and / or the mode of display of the object, and It is automatically modified by computational rules that control the computer to be achieved according to the object content 14-38, the selected preferred settings, and the available display resources on the display screen, while avoiding overlapping of objects. sell.

  Since the object 12 can be automatically changed in this way, it can also be referred to as an intelligent object.

  FIG. 3 is a diagram showing the variability of the representation of the object content and the suppression of less important details of the object content based on two blood pressure displays 40.

  The left side of FIG. 3 is given various possible displays for the display of the pulsating blood pressure mark 42, and the right side of FIG. 3 shows the various possible displays for the display of the non-pulsating blood pressure 44.

  Since it is recognized whether the blood pressure is beating, the display is automatically adapted based on the display mode 42 or 44.

  The various possible displays of the display of pulsating blood pressure 42 illustrate, for example, how the object content is adapted to the reduced object surface according to the calculation rules.

  The explanation starts with the expression in the upper left. A well-known conventional two-line blood pressure representation includes a systolic value 46, a diastolic value 48, and an average value 50 shown in parentheses. In addition, additional information is displayed in the form of indicia 52, physical units 54, and appropriate alarm limits 56. Since the values 46, 48 and 50 are related to the central information, their display is clearly larger than the other information, 52, 54 and 56.

  If only a slight change in the display is required, the central information 46, 48, and 50 can be easily reduced so long as good readability is still compensated. However, the other information 52, 54 and 56 already shown at a smaller scale will retain its original dimensions as further reductions will cause readability problems.

  If further reduction of the object surface is required, the central information 46, 48 and 50 is automatically switched from a two-line display to a single-line display. The other information 52, 54, and 56 are still maintained in their original dimensions as described above. If a smaller display of the object content is required, other less important information such as physical units 54 and alarm limits 56 are automatically erased as shown in FIG.

  The same is true for the display of blood pressure 44 that does not beat. Again, the object content is first simply reduced. If there is less space available for the object, the object content is changed by erasing less important details as described above.

4 and 5 are diagrams illustrating further examples of adapting the object 12 or object content to change display resources. FIG. 4 is also a diagram illustrating the various possibilities of displaying numerical values, ie halothane and CO ₂ , for inspiration and exhalation 58 respectively, and FIG. 5 is derived from the minimum and maximum deviations and It is a figure which shows the change of ST segment in the electrocardiogram 60 with the short-term tendency of a measured value. FIG. 5 shows in particular that the object content can be displayed in different ways.

  The plurality of objects 12 can be grouped and arranged in a hierarchical order. As a result, less important objects 12 can be automatically deleted if necessary, for example. The additional display resources obtained in this way are used for the optimized display of the remaining object 12.

  Combining multiple objects to form a group is particularly useful when, for example, it is necessary to simultaneously shrink / enlarge multiple objects 12 or import these objects onto different display screens. There is a meaning.

  However, automatic adaptation of the object 12 is not limited to the relevant object content 14-36. For example, the automatic adaptation of the object 12, especially the menu button 38, is a control element (mouse control as opposed to input via a rotary knob), control element accuracy (touch screen input is more than input via a mouse cursor) Depending on the type of use (the user is in the immediate vicinity of the user interface or at a more remote location) (not explicitly shown).

  These objects 12, eg, menu buttons 38, may also be in a hierarchical order or a group structure. In accordance with the above description, this combined “control structure”, in particular its display, can be adapted as easily as already described for the object content 14-36. Depending on preference, the combined control structure may be displayed by a simple scrolling list, or may be displayed in the form of a column.

  FIG. 6 shows a further user interface 62 of the kind used for patient monitoring, i.e. with the object 64 magnified for a short time. The object 64 magnified for a short time is a menu button to which a larger display surface is assigned over a short period of time so that it can be better recognized from a distance when touched by the cursor. This short magnified representation of the object can be used for other objects as well. For example, it can be used as what should be referred to as a “magnifying glass” to simplify reading the measurements.

  FIG. 7 is a diagram illustrating a further user interface 66 having a display configured differently. FIG. 7 shows in particular the flexibility with which various objects 12 can be displayed. For example, the user interface 66 does not only show information about a single patient. The upper area of the user interface 66 also contains information about other patients. For this purpose, it was only necessary to combine the necessary objects each time to form a group. However, the optimal display of the grouped objects after importing into the user interface 66 is automatically done according to the calculation rules selected as described above.

FIG. 2 schematically shows a plurality of objects of a user interface used in the field of patient monitoring. FIG. 2 illustrates the user interface of FIG. 1 with associated object content. FIG. 2 shows two objects from a user interface that can be automatically changed. FIG. 5 shows further objects that can be changed automatically. FIG. 6 shows further details of an object from a user interface for patient monitoring. FIG. 5 shows another user interface from the field of patient monitoring with objects magnified for a short time. FIG. 5 shows a further user interface from the field of patient monitoring with a differently configured display.

Explanation of symbols

10 User Interface 12 Object 14 ECG Curve (Derivative I)
16 ECG curve (Derivatives II)
18 Oxygen saturation curve 20 CO ₂ breathing curve 22 Current heart rate numerical display 24 Alarm limit for heart rate numerical display 26 Blood pressure numerical display 28 First body temperature numerical display 30 First body temperature numerical display (different measurement) place)
32 Alarm limit for blood pressure display 34 Alarm limit for first body temperature 36 Alarm limit for second body temperature 38 Menu button 40 Blood pressure display 42 Display of beating blood pressure 44 Display of non-beating blood pressure 46 Value of systole 48 Diastolic value 50 Average value 52 Description 54 Physical unit 56 Alarm limit 58 Halothane and CO ₂ indicated for inspiration and expiration respectively
60 ST segment in ECG 62 User interface 64 Object expanded over a short period of time 66 Further user interface

Claims (14)

A method for optimizing the representation on a display screen of an object of a user interface that can be freely positioned and scaled by a control element,
Optimizing the available display screen surface while possibly suppressing less important details of the object content, changing the object content and / or the mode of display of the object, and avoiding overlapping of objects The object is automatically between the smallest readable dimension and the largest selected dimension according to the object content, the desired setting selected, and the available display resources on the display screen so that proper filling is achieved. The method performed by the control element according to a predetermined calculation rule so that it can be changed to   The object is placed in a fixed hierarchical structure to allow automatic suppression of the object, starting from the lowest hierarchical level if the display resources on the display screen are insufficient. The method of claim 1, characterized in that:   The method according to claim 1 or 2, characterized in that the order of the hierarchically combined objects can be changed.   4. The method according to claim 1, wherein a plurality of objects can be combined to form a group by the control element.   5. A method according to any one of claims 1 to 4, characterized in that the behavior of the objects relative to each other as well as the interaction of the various objects relative to each other associated with the display resource is taken into account.   Method according to claim 5, characterized in that the objects can be automatically replaced with each other.   7. The object according to claim 1, wherein the object can be displayed temporarily in an enlarged form depending on a predetermined trigger signal generated by a control element defined by object selection / object marking. The method according to any one of the above.   8. Object content according to any one of the preceding claims, characterized in that the object content comprises static information as well as dynamically variable information and / or instructions and various options for processing / operations. The method described in the paragraph.   9. A method as claimed in any preceding claim, wherein each rectangular surface is provided to display an object on a display screen.   10. A method according to any one of claims 1 to 9, characterized in that the static and dynamic information of the object content is medical information, in particular information for patient monitoring. An apparatus for simultaneous and compressed optical display of object data on a graphic user interface, comprising an arithmetic unit for performing the method according to any one of claims 1-10.
The arithmetic unit may be used while possibly suppressing less important details of the object content, changing the object content and / or the mode of display of the object, and avoiding overlapping of objects. An apparatus comprising a calculation program for optimizing the display of object data in accordance with predetermined criteria so that an optimized filling of the display screen surface is achieved.   12. A device according to claim 11, characterized in that a control element is provided that can generate a trigger signal for a short time expansion of the selected / marked object.   13. The apparatus according to claim 11, further comprising an input unit that can change the display.   14. Apparatus according to any one of claims 11 to 13, characterized in that the input means cooperates with a medical measuring device that forms static and dynamic information of the object.

Images